Development of silk vascular graft coated with silk sponge

Takashi Tanaka; Tetsuo Asakura

doi:10.37190/abb/214380

Abstract

Purpose: Changes in diet and lifestyle have increased the number of patients with vascular diseases. Synthetic grafts yield unacceptable outcomes in very small vessels, such as coronary arteries, causing the exclusive use of native vessels despite their limited availability and sometimes suboptimal quality. Therefore, a small-diameter vascular graft that achieves outcomes comparable to native vessels is clinically needed.

Methods: In this paper, porous silk fibroin vascular grafts (PSVG) were prepared using a double-raschel knitting machine to create vascular grafts from silk fibers, followed by coating with a silk sponge using poly(ethylene glycol diglycidyl ether) as a porogen. Gelatin-sealed polyethylene terephthalate vascular grafts and non-porous silk vascular grafts were prepared as controls.

Results: When this PSVG was implanted into rats, positive results were observed 4 weeks post-implantation. Specifically, endothelial-like cells were confirmed in the central part of the patent PSVG, indicating that endothelialization had progressed within a relatively short period of 4 weeks. However, gelatin-sealed polyethylene terephthalate vascular grafts and non-porous silk vascular grafts showed no indication of the presence of the endothelial-like cells.

Conclusions: These results indicate that PSVG is promising as small-diameter grafts for implantation.

References

Aigner T.B., DeSimone E., Scheibel T., Biomedical applications of recombinant silk ‐ based materials, Advanced Materials, 2018, 30 (19), 1704636.
Search in Google Scholar Back to article
Al Fahad M.A., Lee H.-Y., Park S., Choi M., Shanto P.C., Park M. et al., Small-diameter vascular graft composing of core-shell structured micro-nanofibers loaded with heparin and VEGF for endothelialization and prevention of neointimal hyperplasia, Biomaterials, 2024, 306, 122507.
Search in Google Scholar Back to article
Al Fahad M.A., Rahaman M.S., Mahbub M.S.I., Park M., Lee H.Y., Lee B.T., Endothelialization and smooth muscle cell regeneration capabilities of a bi-layered small diameter vascular graft for blood vessel reconstruction, Mater Design, 2023, 225.
Search in Google Scholar Back to article
Ao P., Hawthorne W., Vicaretti M., Fletcher J., Development of intimal hyperplasia in six different vascular prostheses, European Journal of Vascular and Endovascular Surgery, 2000, 20 (3), 241–249.
Search in Google Scholar Back to article
Asakura T., Endo M., Fukuhara R., Tasei Y., 13 C NMR characterization of hydrated 13 C labeled Bombyx mori silk fibroin sponges prepared using glycerin, poly (ethylene glycol diglycidyl ether) and poly (ethylene glycol) as porogens, Journal of Materials Chemistry B, 2017, 5 (11), 2152–2160.
Search in Google Scholar Back to article
Asakura T., Kaplan D.L., Encyclopedia of Agricultural Science, Academic Press, London 1994.
Search in Google Scholar Back to article
Bos G.W., Poot A.A., Beugeling T., Van Aken W., Feijen J., Small-diameter vascular graft prostheses: current status, Archives of Physiology and Biochemistry, 1998, 106 (2), 100–115.
Search in Google Scholar Back to article
Enomoto S., Sumi M., Kajimoto K., Nakazawa Y., Takahashi R., Takabayashi C. et al., Long-term patency of small-diameter vascular graft made from fibroin, a silk-based biodegradable material, Journal of Vascular Surgery 2010, 51 (1), 155–164.
Search in Google Scholar Back to article
Fukayama T., Takagi K., Tanaka R., Hatakeyama Y., Aytemiz D., Suzuki Y. et al., Biological reaction to smalldiameter vascular grafts made of silk fibroin implanted in the abdominal aortae of rats, Annals of Vascular Surgery 2015, 29 (2), 341–352.
Search in Google Scholar Back to article
Harskamp R.E., Lopes R.D., Baisden C.E., De Winter R.J., Alexander J.H., Saphenous vein graft failure after coronary artery bypass surgery: pathophysiology, management, and future directions, Annals of Surgery, 2013, 257 (5), 824–833.
Search in Google Scholar Back to article
Haruguchi H., Teraoka S., Intimal hyperplasia and hemodynamic factors in arterial bypass and arteriovenous grafts: a review, Journal of Artificial Organs, 2003, 6 (4), 227–235.
Search in Google Scholar Back to article
Hayashi F., Okuda Y., Nakata M., Natori K., Development of a Small-Diameter Expanded Polytetrafluoroethylene Vascular Graft, Sei Technical Review – English Edition – 2003, 83–88.
Search in Google Scholar Back to article
Holland C., Numata K., Rnjak‐Kovacina J., Seib F.P., The biomedical use of silk: past, present, future, Advanced Healthcare Materials, 2019, 8 (1), 1800465.
Search in Google Scholar Back to article
Horan R.L., Antle K., Collette A.L., Wang Y., Huang J., Moreau J.E. et al., In vitro degradation of silk fibroin, Biomaterials, 2005, 26 (17), 3385–3393.
Search in Google Scholar Back to article
Isenberg B.C., Williams C., Tranquillo R.T., Small-diameter artificial arteries engineered in vitro, Circulation Research, 2006, 98 (1), 25–35.
Search in Google Scholar Back to article
Jana S., Endothelialization of cardiovascular devices, Acta Biomaterialia, 2019, 99, 53–71.
Search in Google Scholar Back to article
Kawecki F., L’Heureux N., Current biofabrication methods for vascular tissue engineering and an introduction to biological textiles, Biofabrication, 2023, 15 (2), 022004.
Search in Google Scholar Back to article
Koh L.-D., Cheng Y., Teng C.-P., Khin Y.-W., Loh X.-J., Tee S.-Y. et al., Structures, mechanical properties and applications of silk fibroin materials, Progress in Polymer Science, 2015, 46, 86–110.
Search in Google Scholar Back to article
Kundu B., Kurland N.E., Bano S., Patra C., Engel F.B., Yadavalli V.K. et al., Silk proteins for biomedical applications: Bioengineering perspectives, Progress in Polymer Science, 2014, 39 (2), 251–267.
Search in Google Scholar Back to article
Kuwabara F., Narita Y., Yamawaki-Ogata A., Satake M., Kaneko H., Oshima H. et al., Long-term results of tissueengineered small-caliber vascular grafts in a rat carotid arterial replacement model, Journal of Artificial Organs, 2012, 15 (4), 399–405.
Search in Google Scholar Back to article
Li M., Ogiso M., Minoura N., Enzymatic degradation behavior of porous silk fibroin sheets, Biomaterials, 2003, 24 (2), 357–365.
Search in Google Scholar Back to article
Lovett M., Eng G., Kluge J., Cannizzaro C., Vunjak-Novakovic G., Kaplan D.L., Tubular silk scaffolds for small diameter vascular grafts, Organogenesis, 2010, 6 (4), 217–224.
Search in Google Scholar Back to article
Mahara A., Somekawa S., Kobayashi N., Hirano Y., Kimura Y., Fujisato T. et al., Tissue-engineered acellular small diameter long-bypass grafts with neointima-inducing activity, Biomaterials, 2015, 58, 54–62.
Search in Google Scholar Back to article
Meinel L., Hofmann S., Karageorgiou V., Kirker-Head C., McCool J., Gronowicz G. et al., The inflammatory responses to silk films in vitro and in vivo, Biomaterials, 2005, 26 (2), 147–155.
Search in Google Scholar Back to article
Min S., Gao X., Han C., Chen Y., Yang M., Zhu L. et al., Preparation of a silk fibroin spongy wound dressing and its therapeutic efficiency in skin defects, Journal of Biomaterials Science, Polymer Edition, 2012, 23 (1–4), 97–110.
Search in Google Scholar Back to article
Min S., Gao X., Liu L., Tian L., Zhu L., Zhang H. et al., Fabrication and characterization of porous tubular silk fibroin scaffolds, Journal of Biomaterials Science, Polymer Edition, 2009, 20 (13), 1961–1974.
Search in Google Scholar Back to article
Narayan D., Venkatraman S., Effect of pore size and interpore distance on endothelial cell growth on polymers, Journal of Biomedical Materials Research Part A: An Official Journal of The Society for Biomaterials, The Japanese Society for Biomaterials, and The Australian Society for Biomaterials and the Korean Society for Biomaterials, 2008, 87 (3), 710–718.
Search in Google Scholar Back to article
Noishiki Y., Tomizawa Y., Yamane Y., Matsumoto A., Autocrine angiogenic vascular prosthesis with bone marrow transplantation, Nature Medicine, 1996, 2 (1), 90–93.
Search in Google Scholar Back to article
Noishiki Y., Yamane Y., Tomizawa Y., Matsumoto A., Transplantation of autologous tissue fragments into an e ‐ PTFE graft with long fibrils, Artificial Organs, 1995, 19 (1), 17–26.
Search in Google Scholar Back to article
Obiweluozor F.O., Emechebe G.A., Kim D.-W., Cho H.-J., Park C.H., Kim C.S. et al., Considerations in the development of small-diameter vascular graft as an alternative for bypass and reconstructive surgeries: a review, Cardiovascular Engineering and Technology, 2020, 11 (5), 495–521.
Search in Google Scholar Back to article
Pashneh-Tala S., MacNeil S., Claeyssens F., The tissueengineered vascular graft — past, present, and future, Tissue Engineering Part B: Reviews, 2016, 22 (1), 68–100.
Search in Google Scholar Back to article
Pektok E., Nottelet B., Tille J.-C., Gurny R., Kalangos A., Moeller M. et al., Degradation and healing characteristics of small-diameter poly ( ε -caprolactone) vascular grafts in the rat systemic arterial circulation, Circulation, 2008, 118 (24), 2563–2570.
Search in Google Scholar Back to article
Pok S., Myers J.D., Madihally S.V., Jacot J.G., A multilayered scaffold of a chitosan and gelatin hydrogel supported by a PCL core for cardiac tissue engineering, Acta Biomaterialia, 2013, 9 (3), 5630–5642
Search in Google Scholar Back to article
Settembrini A., Buongiovanni G., Settembrini P., Alessandrino A., Freddi G., Vettor G. et al., In-vivo evaluation of silk fibroin small-diameter vascular grafts: State of art of preclinical studies and animal models, Frontiers in Surgery, 2023, 10, 1090565.
Search in Google Scholar Back to article
Tai N., Salacinski H., Edwards A., Hamilton G., Seifalian A., Compliance properties of conduits used in vascular reconstruction, Journal of British Surgery, 2000, 87 (11), 1516–1524.
Search in Google Scholar Back to article
Vepari C., Kaplan D.L., Silk as a biomaterial, Progress in Polymer Science, 2007, 32 (8–9), 991–1007.
Search in Google Scholar Back to article
Xiang P., Wang S.-S., He M., Han Y.-H., Zhou Z.-H., Chen D.-L. et al., The in vitro and in vivo biocompatibility evaluation of electrospun recombinant spider silk protein/PCL/gelatin for small caliber vascular tissue engineering scaffolds, Colloids and Surfaces B: Biointerfaces, 2018, 163, 19–28.
Search in Google Scholar Back to article
Xu W., Ke G., Peng X., Studies on the effects of the enzymatic treatment on silk fine powder, Journal of Applied Polymer Science, 2006, 101 (5), 2967–2971.
Search in Google Scholar Back to article
Yoshimizu H., Asakura T., Preparation and characterization of silk fibroin powder and its application to enzyme immobilization, Journal of Applied Polymer Science, 1990, 40 (1–2), 127–134.
Search in Google Scholar Back to article
Zhu C., Fan D., Wang Y., Human-like collagen/hyaluronic acid 3D scaffolds for vascular tissue engineering, Materials Science and Engineering: C, 2014, 34, 393–401.
Search in Google Scholar Back to article

Development of silk vascular graft coated with silk sponge

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